Fullerene-doped nanostructures and methods therefor

ABSTRACT

Nanostructures are doped to set conductivity characteristics. In accordance with various example embodiments, nanostructures such as carbon nanotubes are doped with a halogenated fullerene type of dopant material. In some implementations, the dopant material is deposited from solution or by vapor deposition, and used to dope the nanotubes to increase the thermal and/or electrical conductivity of the nanotubes.

RELATED PATENT DOCUMENT

This patent document is a divisional under 35 U.S.C. §120 of U.S. patent application Ser. No. 13/011,402 filed on Jan. 21, 2011 (U.S. Pat. No. 8,530,271), which claims benefit under 35 U.S.C. §119 to U.S. Provisional Patent Application Ser. No. 61/298,043 entitled “Fullerene-Doped Nanostructures” and filed on Jan. 25, 2010; each of these patent documents is fully incorporated herein by reference.

FEDERALLY-SPONSORED RESEARCH AND DEVELOPMENT

This invention was made with Government support under contracts HM1582-07-1-2009 awarded by the National Geospatial-Intelligence Agency and 0213618 awarded by the National Science Foundation. The U.S. Government has certain rights in this invention.

FIELD

The present invention relates generally to nanostructures, and more specifically, to doped nanostructures and methods therefor.

BACKGROUND

Nanostructures, such as carbon nanotube (CNT) and graphene-based materials, have been increasingly used in a multitude of disparate applications. For example, some CNT-based applications have involved electronic circuits, bio-functionalized devices, transistors, displays, touch screens, OLEDs, e-readers, solar cells and sensors for security, chemical, and biological applications. In many of these applications, thin, highly conductive materials are desirable.

For many of these applications, manufacturing nanotubes having consistent properties has been difficult under many conditions, and particularly under high-volume production conditions. For example, nanotubes often have different shapes, or chiralities, and different conductivity and electronic characteristics (e.g., nanotube fabrication can result in both semiconducting and metallic nanotubes).

In view of the above, nanostructures such as nanotubes and graphene have been manipulated or otherwise modified to suit specific applications. For instance, carbon nanotubes have been doped using dopants such as iodine, silver chloride and thionyl chloride, which can improve the conductivity of CNTs. However, such dopants can be challenging to implement for large-scale manufacturing and real-world applications. For example, certain dopants involve or otherwise require the use of gases that are undesirable (e.g., toxic) or difficult to use, and many dopants have not been capable of use in forming doped structures that are stable over time. Certain dopants can degrade carbon nanotubes and other organic materials over time, preventing encapsulation and making the doped structures unsuitable for many applications. In addition, many approaches to doping or otherwise modifying carbon nanotubes have involved undesirable and/or expensive manufacturing processes, such as those involving high heat or lengthy throughput.

These and other issues remain as a challenge to a variety of methods, devices and systems that use or benefit from nanostructures.

SUMMARY

Various aspects of the present invention are directed to devices, methods and systems involving nanostructures that address challenges including those discussed above.

According to an example embodiment, a nanostructure is doped using a fullerene-based material. The fullerene-based material, such as a halogenated fullerene (e.g., a fluorinated fullerene), is applied to the nanostructure and nucleated. The nucleated fullerene-based material dopes the nanostructure with a dopant from the nucleated fullerene-based material.

Another example embodiment is directed to a method for doping a nanostructure, as follows. A fullerene-based material is applied to an outer surface of the nanostructure. This fullerene-based material has a Fermi level that is below the Fermi level and/or the conduction band energy of the nanostructure, and is used to grow a fullerene-based dopant material on the nanostructure. The surface of the nanostructure is doped with a dopant from the fullerene-based dopant material to form a hybrid material including a portion of the nanostructure and the dopant. The hybrid material exhibits a conductivity that is greater than a conductivity of the nanostructure, prior to doping via the fullerene-based dopant material.

Another example embodiment is directed to a method for doping a carbon-based nanowire, such as a single nanowire and/or a portion of a circuit. A fullerene-based material, which includes a material selected from the group of C₆₀F₁₈, C₆₀F₂₄, C₆₀F₃₆, C₆₀F₄₈, C₆₀F₄₄ and C₇₀F₅₄ is applied to a carbon-based nanowire. The (fluorinated) fullerene-based material is nucleated to form a nucleated fullerene-based material on the carbon-based nanowire circuit, and to dope the carbon-based nanowire circuit with the (fluorinated) fullerene.

Another example embodiment is directed to a carbon-based nanowire having a semiconducting carbon-based nanomaterial and a conductive hybrid material, which includes a halogenated (e.g., fluorinated) fullerene dopant and the carbon-based nanomaterial. The hybrid material exhibits a conductivity that increases the conductivity of the semiconducting carbon-based nanowire, relative to the conductivity of the carbon-based nanomaterial.

The above summary is not intended to describe each embodiment or every implementation of the present disclosure. The figures and detailed description that follow more particularly exemplify various embodiments.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention may be more completely understood in consideration of the following detailed description of various embodiments of the invention in connection with the accompanying drawings, in which.

FIG. 1 shows a nanostructure at various stages of a doping process, according to an example embodiment of the present invention;

FIG. 2 shows energy levels for carbon nanotubes doped in accordance with various example embodiments of the present invention; and

FIG. 3 is a histogram showing carbon nanotubes doped in accordance with various example embodiments of the present invention.

While the invention is amenable to various modifications and alternative forms, specifics thereof have been shown by way of example in the drawings and will be described in detail. It should be understood, however, that the intention is not to limit the invention to the particular embodiments described. On the contrary, the intention is to cover all modifications, equivalents, and alternatives falling within the scope of the invention including aspects defined in the claims.

DETAILED DESCRIPTION

The present invention relates to doping nanomaterials as described herein. While the present invention is not necessarily limited to such devices and applications, various aspects of the invention may be appreciated through a discussion of examples using these and other contexts.

According to an example embodiment, halogenated fullerenes are used to dope nanostructures such as carbon nanotubes. In one embodiment, one or more fluorinated fullerene dopants are deposited, grown or otherwise placed onto carbon or inorganic based nano/micro structures. The intimate contact of the dopant(s) with the nano/micro structure is used to effect charge transfer and doping of the nano/micro structure, to set (e.g., improve) the nano/micro structure's electrical and/or thermal conductivity. In certain applications, the dopants also enhance the strength, rigidity or other mechanical properties of the nano/micro structure.

The dopant material can be deposited or otherwise formed upon a target structure using a variety of approaches. In some applications, the dopant is deposited from a vapor phase, such as by using thermal vapor deposition. In other applications, the dopant is deposited from a solution. Still other applications involve the deposition of a dopant from other approaches, or using a combination of approaches (e.g., solution-based and vapor-based deposition), which can be carried out concurrently and/or in different steps. Once deposited or formed, the dopant material is used to dope the target structure, and may be further modified via treatment (before or after doping).

A variety of dopants can be used for different applications. In some applications, the dopant is selected and used to increase the conductivity of a micro/nano structure by more than two orders of magnitude. For various applications, dopants are selected for stability, and used to generate an electronic and/or thermal device that exhibits stable doped properties over time (e.g., indefinitely in ambient temperature conditions and/or up to and exceeding about 250 degrees Celsius).

In many applications, a dopant that is selective to the nano/micro structure to which it is applied is used to dope the nano/micro structure. For example, in many applications, it is desirable to limit the deposition of a dopant to a particular nanostructure. Accordingly, one or more dopant materials that selectively grow upon the particular nanostructure, relative to surrounding nanostructures and/or an underlying substrate, are grown on the nanostructure while mitigating or eliminating the growth of the dopant materials upon other structures.

In connection with various example embodiments, halogenated fullerenes are used to dope carbon and inorganic nano/micro structures for applications including nano/micro tube or wire-based electronic devices such as transistors, displays, touch screens, sensors, electronic paper (e-paper), electronic readers (e-readers), flexible electronic devices, solar cells, thermal conductors, and composite materials. The dopant is chosen to stably and efficiently dope semiconducting nano/micro structures to set the conductivity level of the structures, such as by increasing the conductivity of a semiconducting nanotube and/or by doping a semiconducting nanotube to form a metallic nanotube. For various applications, the dopant is chosen to set electrical charge transport characteristics of a nano/micro structure as described herein.

In these contexts, the term doping refers to the addition of one or more materials in contact with the nano/micro structure. The additional doping material, or dopant, introduces free and mobile charges into the conduction band of the nano/micro structures. The addition of the free mobile charges in the conduction band is used to set or change the electronic and thermal behavior of a semiconducting material, such as to modify this behavior to resemble structures having metallic-like characteristics. More detail with regard to exemplary doped nano/micro structures, and dopants used, is discussed below.

In some example embodiments, nanotubes are doped using one or more dopants selected from a class of fluorinated fullerene derivatives having the molecular formula: In some example embodiments, nanotubes are doped using one or more dopants selected from a class of halogenated fullerene derivatives and at least part of the molecular formula contains:

C₆F_(x), C₆₀Cl_(y), C₆₀F_(x)Cl_(y), C₇₀F_(x), C₇₀Cl_(y), C₇₀F_(x)Cl_(y)

where X=1-55, for C60 and less than 65 for C70. More preferably, X=18, 24, 36, 48, 54 or 56. Where Y=1-55, for C60, and less than 65 for C70. More preferably, Y=4, 6, 24, 36, 48, 54, or 56. The nanostructure that is doped includes one or more of an individual nanotube, carbon fiber, nanowire, carbon nanotube or other nano/micro structure as described herein.

In some embodiments, carbon nanotubes (CNTs) and/or carbon fibers are doped using a fluorinated fullerene having the formula C₆₀F_(x) as discussed above. For several applications as described herein, a mixture of semiconducting and metallic tubes is modified via doping with such a fluorinated fullerene to dope the semiconducting tubes, and increase the overall thermal and/or electrical conductivity of the mixture. The carbon-based nano/micro structure may include one or more of single walled carbon nanotubes (SWNT) or multi-walled carbon nanotubes (MWCNT), and may include such nanotubes of one or more chiralities. In addition, the carbon-based nano/micro structure may include a bundle of nanotubes, CNTs or a carbon fiber.

Other embodiments are directed to the doping of a graphene-based structure, in which one to several thin layers of graphene is/are doped to suit a particular application or applications. For example, graphene layers can be doped to set their conductivity or other properties to a selected level for one or more of electronic, thermal, and high strength applications. In some implementations, graphene oxide or reduced graphene oxide is doped for such applications, including those desirably involving certain processing characteristics that are achieved using graphene oxide. These approaches (doping of graphene and graphene oxide) are amenable for improving electronic and thermal conductivities of such structures to create viable components in many applications and are suitable for various technologies.

In accordance with another example embodiment, inorganic nano/micro structures such as inorganic semiconductors are doped using a halogenated fullerene as discussed herein, to form electronic circuits and/or devices. In some applications, inorganic micro/nano structures such as those including zinc oxide, silicon, germanium; metal/non-metal semiconductors such as cadmium telluride, zinc-sulfide, titanium nitride, and copper indium gallium selenide; and other metal/non-metal oxides are doped to form electronic circuits.

The various embodiments as described herein may be implemented in connection with one or more of the figures and/or example embodiments. As used in connection with various example embodiments herein (above and as follows), the term “nanostructure” may refer to structures having dimensional characteristics on a nanometer scale, such as carbon nanotubes often having a diameter in the range of about one nanometer (and lengths that may well exceed thousands of nanometers). In other embodiments, the term “nanostructure” refers to structures having dimensional characteristics on the scale of hundreds of nanometers, nearing (and perhaps exceeding) one micrometer, such as carbon fibers having diameters ranging from several hundred nanometers to several micrometers.

In addition, the doping approaches described herein are applicable to doping single nanostructures, such as a single CNT or graphene particle, or to doping a multitude of such structures, which may be arranged in the form of a wire, circuit, sheet or other device. For instance, some applications are directed to doping CNTs that are joined or otherwise connected, using approaches such as laser ablation, soldering, substrate fixation and welding. For certain embodiments, the doping approach described herein may facilitate such joining as well (e.g., deposited dopant materials may also act to join nanostructures), and may also facilitate the enhancement of the mechanical strength of the structures that are doped.

In certain embodiments, nanostructures such as CNTs or graphene are dispersed in a solution, such as a surfactant or polymer-based solution, and deposited from the solution. In these embodiments, surfactants or polymers may cover some of or the entire surface of the CNT or graphene, and a dopant material as described herein is deposited on the covered surface. Charge transfer in such structures may be effected either through exposed regions of the CNT or graphene, or via charge transfer to the coating on the surface and further through the coating to the CNT or graphene.

In various contexts, the terms “nanowire” and “circuit” as described herein apply to a conductor that forms part of a circuit, and/or to a circuit having a conductor and other components. For example, the term circuit may refer to a conductor or conductive sheet that can be powered and coupled to one or more circuit components. The term circuit may also refer to such a conductor or conductive sheet, along with one or more circuit components.

Turning now to the Figures, FIG. 1 shows a nanostructure 100 at various stages of a doping process, according to another example embodiment of the present invention. A nanotube 110 at A is shown by way of example, while the approach shown and described as follows can be used in connection with a variety of nanostructures or microstructures, as discussed above. For example, one or more of CNTs, single-walled nanotubes (SWNTs), multi-walled carbon nanotubes (MWCNTs), carbon fibers, nanowires, nanomaterial tows, and nanomaterial ropes (e.g., bundles of ranging diameter) can be formed as shown. Different types of nanomaterials may also be used, such as those discussed above, nanotubes with varying chirality (e.g., semiconducting or metallic), semiconducting nanotubes, metallic nanotubes, inorganic and organic nanowire (e.g., with one or more of ZnO, Ag, Au or Si), or a combination thereof. In addition, while one nanotube 110 is shown, a multitude of such nanotubes (or nanostructures) can be doped as described herein, concurrently and/or as part of different manufacturing steps.

The resulting structure may be used to form a variety of devices such as a conductive wire, circuits and/or an entire film of these nanostructures. The density, alignment, length, and overall thickness (e.g., ranging from 1-100 nm or much higher) of the dopant upon the nanotube 110 can also be set to suit particular applications. In addition, the nanotube 110 can be free standing or formed upon a substrate.

A dopant material is deposited on the nanotube 110 at B, such as from solution or from vapor, and the deposited dopant material 120 is used to dope the nanotube at C to set (e.g., increase) the conductivity of the nanotube. The dopant material may include a fluorinated fullerene material as discussed above, as well as other variants of such material (e.g., the dopant may include a substituted fullerene material selected from the group of: C₆₀F₁₈, C₆₀F₂₄, C₆₀F₃₆, C₆₀F₄₈, C₆₀F₄₄ and C₇₀F₅₄ or other halogenated fullerenes—for example, chlorinated fullerenes). In some implementations, the dopant material is nucleated at C (e.g., the material nucleates upon deposition) to form a nucleated dopant and/or as part of a process used to dope the nanotube 110, which can also be used to set or otherwise control the level of doping. The dopant material can be grown along some or all of the nanotube 110, extending from one or more initial nucleation sites, as part of the deposition/nucleation at a nucleation site and/or as part of continued deposition or another deposition process.

Generally, the doping can be carried out across nanostructures as shown (e.g., across the nanotube 110), or across an entire film of such nanostructures, to form a plurality of conductive structures. In many implementations involving the doping of a film, the Fermi level of the dopant used across the film is less than the Fermi level of a majority of or substantially all of the nanostructures (e.g., more than 75%, more than 85%, or more than 95% of the nanostructures). Where a mixture of nanostructures is present in the film (e.g., semiconducting and metallic nanowires), the Fermi level of the dopant used in the film can be less than a majority of or substantially all of one type of the nanostructures (e.g., the semiconducting nanostructures).

FIG. 2 is a chart 200 showing exemplary energy levels for carbon nanotubes doped in accordance with various example embodiments of the present invention. These exemplary energy levels, (highest occupied molecular orbital (HOMO), and lowest unoccupied molecular orbital (LUMO) are shown for carbon nanotubes doped with different fluorinated dopants, with exemplary values also shown for an un-doped carbon nanotube.

In accordance with various example embodiments, one or more of the dopants as shown in FIG. 2 are used to attain different levels of conductivity in carbon nanotubes. The dopants may be selected based upon a desired conductivity for a particular application, cost or other characteristics of the dopants, or other aspects of devices to be formed using the doped carbon nanotubes. In addition, the amount of dopant used can be set to achieve a desired dopant level (e.g., as shown, fluorinated fullerenes are deposited to a thickness of about 5 nanometers).

Energy levels are shown for a carbon nanotube at 210, and for such a carbon nanotube doped with fluorinated fullerenes including C₆₀F₁₈, C₆₀F₃₆, and C₆₀F₄₈, as respectively shown at 220, 230 and 240. Using the electronegativity of fluorine (F), increased fluorine content is used to greatly lower the fullerene's lowest unoccupied molecular orbital (LUMO). The addition of each F-atom is used to set or lower the LUMO to about 0.05 eV. Correspondingly, one or more other types of halogens may be similarly implemented. In connection with these embodiments, it has been discovered that the Fermi energy of all of fluorinated fullerenes (FFs) is lower than the CNT Fermi energy, and that similar approaches are applicable with other halogens.

Upon equilibration of the CNTs and FF system, the Fermi energies are equalized by electron transfer from the CNT to the FF, which p-dopes (introduces holes) into the CNT. The lowest unoccupied molecular orbitals of C₆₀F₃₆, and C₆₀F₄₈ can be lower in energy than the CNT HOMO, which is used to facilitate efficient charge-transfer doping.

FIG. 3 is a histogram 300 showing carbon nanotubes doped in accordance with various example embodiments of the present invention. An undoped carbon nanotube is represented at 310, and carbon nanotubes doped with fluorinated fullerenes C₆₀F₁₈, C₆₀F₃₆, and C₆₀F₄₈ are respectively shown at 320, 330 and 340.

In connection with these embodiments, it has been recognized/discovered that the doping efficiency, and CNT conductivity, increases with fluorination as shown in FIG. 3. For example, in connection with various experimental embodiments, it has been recognized that the difference in energies between the HOMO of a CNT and the LUMO of a CNT doped with C₆₀F₄₈,

(E_(CNT-HOMO)−EC₆₀ _(F) ₄₈ _(-LUMO) )

is about ca 0.8 eV (e.g., indicating a doping efficiency of at least unity). Each C₆₀F₄₈ molecule in contact with a semiconducting-CNT is used to add at least one hole to the CNT.

In one experimental-type embodiment, the hole concentration (p in holes/cm²) is related to the sheet resistance, SC-CNT mobility μ (˜5-50 cm²/Vs) and elementary charge e by, p=(eμRs)⁻¹ and can be set to be around 10¹²-10¹⁵ holes/cm². The monolayer coverage for one layer of C₆₀F₄₈ is ˜8×10¹³ molecules/cm², which is less than the hole concentration, where the C₆₀F₄₈ is also doping the CNTs at the sidewalls. The doping efficiency may thus exceed unity, and in some implementations, the C₆₀F₄₈ is used to accept two electrons in the LUMO.

In accordance with the above, various embodiments are directed to setting the transparency of a doped nano/microstructure by setting the amount of dopant material. For example, using more dopant material may increase electrical and/or thermal conductivity, yet this may also hinder transparency. In this regard, various embodiments are directed to using a dopant material at an amount that meets desired conductivity levels as well as desired levels of transparency, with trade-offs between conductivity and transparency set for the desired application. In one example implementation, the sheet resistance is set to about 600 Ohms at about 96% transparency on a C₆₀F₄₈-doped sparse semiconducting-CNT.

In accordance with various example embodiments and as discovered in connection with the same, in terms of transparency and overall film thickness (which can be set for specific device applications), fluorinated fullerene (C₆₀F_(x)) as discussed herein is used to preferentially grow on carbon nanotubes relative to an underlying substrate upon which the carbon nanotubes are grown. In one implementation, low or minimal loss in transparency is achieved after the deposition of C₆₀F₄₈ (as shown in FIGS. 2 and/or 3) onto carbon nanotubes, in accordance with the relatively large band gap and (white) color of C₆₀F₄₈, making it a poor absorber of light. In some implementations, sheet resistances under 150 Ohms at about 91% transparency are achieved, and in other implementations, sheet resistances of about 60 Ohms are achieved at a transparency of about 92% for joined nanotubes.

Various embodiments described above and shown in the figures may be implemented together and/or in other manners. One or more of the items depicted in the drawings/figures can also be implemented in a more separated or integrated manner, or removed and/or rendered as inoperable in certain cases, as is useful in accordance with particular applications. For example, various embodiments directed to nanostructures may be implemented with microstructures, such as those having diameters or other dimensional characteristics on the order of about 1 nanometer to hundreds of nanometers. Similarly, embodiments characterized using carbon-based structures may be implemented with non-carbon-based structures (e.g., nanotubes of other materials or of hybrid carbon materials), and embodiments involving nanotubes may be implemented using nanowires and carbon fibers, instead of and/or in addition to nanotubes. Moreover, a variety of different doping materials may be used in different applications. In view of the description herein, those skilled in the art will recognize that many changes may be made thereto without departing from the spirit and scope of the present invention. 

What is claimed is:
 1. An apparatus comprising: a semiconducting carbon nanotube-based nanomaterial coupled between circuit nodes; and a conductive hybrid material including a halogenated fullerene dopant and the carbon nanotube-based nanomaterial, the dopant configured to effect a charge transfer to the carbon nanotube-based nanomaterial, and configured to electrically couple the circuit nodes, the hybrid material exhibiting a conductivity that is higher than a conductivity of the carbon nanotube-based nanomaterial.
 2. The apparatus of claim 1, wherein the dopant includes a material selected from the group of C₆₀F₁₈, C₆₀F₂₄, C₆₀F₃₆, and C₆₀F₄₈, C₆₀F₄₄ and C₇₀F₅₄.
 3. The apparatus of claim 1, wherein the conductive hybrid material has a resistance value that is an order of magnitude less than a resistance value of the semiconducting carbon nanotube-based nanomaterial.
 4. The apparatus of claim 1, wherein the conductive hybrid material is configured and arranged with the nanowire to render the nanowire more thermally conductive than the semiconducting carbon nanotube-based nanomaterial.
 5. The apparatus of claim 1, wherein the semiconducting carbon nanotube-based nanomaterial is a carbon nanotube, and the conductive hybrid material is a sidewall of the carbon nanotube doped with the halogenated fullerene dopant.
 6. The apparatus of claim 1, wherein the semiconducting carbon nanotube-based nanomaterial and the conductive hybrid material are configured and arranged into a nanowire circuit.
 7. The apparatus of claim 6, wherein the nanowire circuit exhibits respective degrees of transparency and conductivity set for touch screens.
 8. The apparatus of claim 7, wherein the degree of transparency is over 90%.
 9. The apparatus of claim 6, wherein the nanowire circuit exhibits respective degrees of transparency and conductivity set for solar cells.
 10. The apparatus of claim 9, wherein the degree of transparency is over 90%.
 11. The apparatus of claim 6, wherein the nanowire circuit manifests sheet resistance between 60 Ohms and 150 Ohms and transparency over 90%.
 12. The apparatus of claim 1, wherein the dopant includes a material selected from the group of C₆₀F₁₈, C₆₀F₂₄, C₆₀F₃₆.
 13. The apparatus of claim 1, wherein the dopant includes a material selected from the group of C₆₀F₄₈, C₆₀F₄₄ and C₇₀F₅₄.
 14. The apparatus of claim 1, wherein the dopant includes a material selected from the group of C₆₀F₁₈, C₆₀F₂₄, C₆₀F₃₆, and the semiconducting carbon nanotube-based nanomaterial and the conductive hybrid material are configured and arranged into a nanowire circuit.
 15. The apparatus of claim 1, wherein the dopant includes a material selected from the group of C₆₀F₄₈, C₆₀F₄₄ and C₇₀F₅₄, and the semiconducting carbon nanotube-based nanomaterial and the conductive hybrid material are configured and arranged into a nanowire circuit.
 16. The apparatus of claim 1, wherein the semiconducting carbon nanotube-based nanomaterial and the conductive hybrid material are configured and arranged into a nanowire circuit, the nanowire circuit exhibits respective degrees of transparency and conductivity set for touch screens, and the dopant includes a material selected from the group of C₆₀F₁₈, C₆₀F₂₄, C₆₀F₃₆.
 17. The apparatus of claim 1, wherein the semiconducting carbon nanotube-based nanomaterial and the conductive hybrid material are configured and arranged into a nanowire circuit, the nanowire circuit exhibits respective degrees of transparency and conductivity set for solar cells, and the dopant includes a material selected from the group of C₆₀F₁₈, C₆₀F₂₄, C₆₀F₃₆.
 18. The apparatus of claim 1, wherein the semiconducting carbon nanotube-based nanomaterial and the conductive hybrid material are configured and arranged into a nanowire circuit, the nanowire circuit exhibits respective degrees of transparency and conductivity set for solar cells, and the dopant includes a material selected from the group of C₆₀F₄₈, C₆₀F₄₄ and C₇₀F₅₄.
 19. The apparatus of claim 1, wherein the dopant includes a material selected from the group of C₆₀F₁₈, C₆₀F₂₄, C₆₀F₃₆, and C₆₀F₄₈, C₆₀F₄₄ and C₇₀F₅₄, the semiconducting carbon nanotube-based nanomaterial and the conductive hybrid material are configured and arranged into a nanowire circuit, and the nanowire circuit manifests sheet resistance between 60 Ohms and 150 Ohms and transparency over 90%. 